Modular adapters for mobile ophthalmoscopy

ABSTRACT

Modular lens adapter system are provided for use with a hand held computer device having a camera for mobile ophthalmoscopy. The modular lens adapter systems include an anterior adapter and a posterior adapter configured to removably engage with a hand held computer device. The anterior adapter can include a variable intensity light source, a clamp, and a movable macro lens. The posterior adapter can include a hand held computer device mount, a lens mount, and a telescoping arm with a first end and a second end with the first end configured to removably engage with the mount and the second end configured to contact the lens mount. Methods are also provided for using the systems to obtain an image of an anterior portion of the patient&#39;s eye and a posterior portion of the patient&#39;s eye.

CROSS REFERENCE TO RELATED APPLICATIONS

This application claims the benefit of U.S. Provisional PatentApplication No. 62/138,271, filed Mar. 25, 2015, titled “MODULARSMARTPHONE ADAPTERS FOR MOBILE OPHTHALMOSCOPY,” which is hereinincorporated by reference in its entirety.

INCORPORATION BY REFERENCE

All publications and patent applications mentioned in this specificationare herein incorporated by reference in their entirety to the sameextent as if each individual publication or patent application wasspecifically and individually indicated to be incorporated by reference.

FIELD

This invention relates generally to ophthalmoscopy. In particular, theinvention relates to lens adapters for mobile ophthalmoscopy that can beused in a modular fashion with mobile imaging devices, like smartphonesand tablet computers.

BACKGROUND

Over the past decade, ophthalmic imaging has moved rapidly from film todigital. However, most of today's gold standard digital fundus cameras,for example, are large, expensive tabletop medical devices onlyavailable in eye clinics. With the advent of the smartphone and everimproving built-in cameras rivaling point-and-shoot pocket digitalcameras, eye care providers have the opportunity to capture high qualityimages anywhere using their existing lenses without the need forexpensive equipment. Combined with ubiquitous fast wireless internet,cloud storage, smartphone-enabled electronic medical records, andencrypted messaging, a modern smartphone can now be instantlytransformed into a low cost, portable, ophthalmic imaging camera. Thepresent disclosure advances the art by providing a customizable adaptersystem or kit for mobile anterior and posterior segment ophthalmoscopy.

SUMMARY OF THE DISCLOSURE

The present invention relates generally to a modular adapter with ananterior adapter and a posterior adapter that can removably engaged witha hand held computer device having a camera.

In general, in one embodiment, a modular lens adapter system includingan anterior adapter configured to removably engage with a hand heldcomputer device having a camera, the anterior adapter includes avariable-intensity light source, a clamp configured to removably engagedwith the hand held computer device, and a movable macro lens configuredto move the macro lens from a first position in coaxial alignment withan optical axis of the hand held computer device camera to a secondposition outside of the optical axis of the camera, the macro lensconfigured to image an anterior portion of an eye; and a posterioradapter with a mount configured to removably engage with the hand heldcomputer device by contacting opposing sides of the hand held computerdevice, the posterior adapter includes a lens mount and a telescopingarm with a first end and a second end, the first end configured toremovably engage with the mount and the second end configured to contactthe lens mount, wherein the lens mount is configured to removably mounta posterior segment ophthalmoscopy lens configured for indirectophthalmoscopy.

This and other embodiments can include one or more of the followingfeatures. The lens mount can be configured to fold relative to thetelescoping arm. The lens mount can include an opening in an outerdiameter of the lens mount, the opening can be configured to accommodatea shaft portion of the telescoping arm when the lens mount is in afolded position. The lens mount can be configured to be folded to beparallel and flush with the telescoping arm. The anterior adapter canfurther include a macro lens hinge configured to move the macro lensfrom the first position to the second position. The anterior adapter canfurther include a macro lens engagement surface configured to secure themacro lens in the first position in coaxial alignment with the opticalaxis of the hand held computer device camera and prevent rotation of themacro lens about the macro lens hinge to a position outside of the firstposition. The modular lens adapter can further include a macro lensholder adapted to hold the macro lens, the macro lens holder can beengaged with the macro lens hinge, wherein the macro lens engagementsurface can further include a complementary surface to the macro lensholder. The anterior adapter can further include a removable batterysource adapted to power the variable intensity light source. Thevariable intensity light source can include a light emitting diode(LED). The anterior adapter can be configured to engage with the handheld computer device adapter at more than one position relative to thehand held computer device. The anterior adapter can be configured toengage with more than one brand of hand held computer device. The clampof the anterior adapter can include a spring to secure the clamp andanterior adapter relative to the hand held computer device. The clamp ofthe anterior adapter can include a first surface and a second surface,the first surface and second surface movable relative to each other suchthat the first surface and second surface can be configured to apply acompressive force against the hand held computer device. The firstsurface and second surface can be configured to apply a compressiveforce to a plurality of different hand held computer device shapes. Themount of the posterior adapter can have a dominant axis with a lengththat can be adjusted to a plurality of different lengths. The mount caninclude a first hand held computer device contact surface and a secondhand held computer device contact surface defining the dominant axis.The posterior adapter can further include a locking mechanism configuredto hold the length of the dominant axis of the mount. The lockingmechanism can further be configured to secure the telescoping armrelative to the mount. The telescoping arm can be configured to bemovable and lockable along a portion of the dominant axis of the mount.The locking mechanism can include a thumb screw. The modular lensadapter can include an open optical pathway between the macro lens andthe lens mount. The modular lens adapter can further include a patientface engagement surface adjacent the lens mount. The anterior adapterand posterior adapter can be configured to be placed in a pocket. Thetelescoping arm can position the lens mount from the mount in a range of1 cm to 20 cm. The modular lens adapter can further include a lightcollimating element configured to be used with the variable intensitylight source. The light collimating element can be movable from aposition in an optical light path of the variable intensity light sourceand a second position outside of the optical light path of the variableintensity light source. The light collimating element can be removablefrom the anterior adapter. The modular lens adapter can further includea modular optical light guide adapted to guide an optical light path ofthe variable intensity light source to coincide with an optical axis ofthe macro lens and hand held computer device camera. The modular opticallight guide can further include a system of mirrors. The modular opticallight guide can further include a rhomboid prism. The rhomboid prism caninclude a first surface configured to reflect light from the variableintensity light source towards the optical pathway of the hand heldcomputer device camera and a second surface configured to reflect lightfrom the first surface to be substantially parallel to the opticalpathway of the hand held computer device camera. The rhomboid prism caninclude a first surface configured to reflect light from the variableintensity light source towards the optical pathway of the hand heldcomputer device camera and a second surface configured to reflect lightfrom the first surface to substantially coincide with the opticalpathway of the hand held computer device camera. The modular opticallight guide can be configured to be removable from the anterior adapter.The modular optical light guide can be configured to be movable relativeto the variable intensity light source between a position in line withthe optical light path of the variable intensity light source and asecond position outside of the optical light path of the variableintensity light source. The modular optical light guide can beconfigured for direct ophthalmoscopy with the anterior adapter. The handheld computer device can be a smartphone, tablet, or other flatscreencomputer device. The modular lens adapter can further include apolarizing filter. The polarizing filter can be a linearly polarizingfilter. The polarizing filter can be a circularly polarizing filter. Theanterior and posterior adapters can be reversibly connected to eachother to create a 3-point fixation to the hand held computer device.

In general, in one embodiment, a method of imaging an anterior portionof a patient's eye, the method including clamping an anterior adapter toa hand held computer device having a camera, the anterior adapterincluding a variable intensity light source, a clamp configured toengage with the hand held computer device, and a movable macro lensconfigured to move the macro lens from a first position in coaxialalignment with an optical axis of the camera to a second positionoutside of the optical axis of the camera, the macro lens configured toimage an anterior portion of the patient's eye; moving the macro lens tobe in coaxial alignment with the optical axis of the camera of the handheld computer device; moving the hand held computer device and anterioradapter to focus on the anterior portion of the patient's eye; andreceiving an image of the anterior portion of the patient's eye with thecamera of the hand held computer device.

This and other embodiments can include one or more of the followingfeatures. The method can further include adjusting the variableintensity light source to provide a desired level of light from thevariable intensity light source to the anterior portion of the patient'seye. The method can further include lining up the optical axis of thecamera with an optical axis of the anterior adapter prior to clampingthe anterior adapter. The anterior adapter can be any of the anterioradapters. The method can further include securing the macro lens in thefirst position by rotating the macro lens about a macro lens hinge ofthe anterior adapter and engaging the macro lens with a macro lensengagement surface of the anterior adapter, the macro lens engagementsurface configured to secure the macro lens in the first position incoaxial alignment with the optical axis of the hand held computer devicecamera and prevent rotation of the macro lens about the macro lens hingeto a position outside of the first position.

In general, in one embodiment, a method of imaging a posterior portionof a patient's eye, the method including securing a mount of a posterioradapter to a hand held computer device including a camera, the posterioradapter including a telescoping arm with a first end and a second end,the first end configured to removably engage with the mount and thesecond end configured to contact a lens mount configured to removablymount a posterior segment ophthalmoscopy lens configured for indirectophthalmoscopy; adjusting the telescoping arm along an axis of the mountto coaxially line up the lens mount with an optical axis of the cameraof the hand held computer device; engaging a lens configured forindirect ophthalmoscopy with the lens mount; moving the hand heldcomputer device and the posterior adapter to focus on the posteriorportion of the patient's eye; adjusting a length of the telescoping armto focus the camera of the hand held computer device on an image of theposterior portion of the patient's eye in the lens configured forindirect ophthalmoscopy; and receiving an image of the posterior portionof the patient's eye with the camera of the hand held computer device.

This and other embodiments can include one or more of the followingfeatures. The method can further include securing the mount of theposterior adapter by adjusting a length of the axis of the mount toaccommodate a dimension of the hand held computer device. The method canfurther include engaging a first hand held computer device contactsurface and a second hand held computer device contact surface of themount with the hand held computer device. The method can further includelocking a length of the axis of the mount to secure the mount relativeto the hand held computer device. The method can further include lockinga position of the telescoping arm along the axis of the mount afteradjusting the telescoping arm along the axis of the mount to coaxiallyline up the lens mount with the optical axis of the camera of the handheld computer device. The posterior adapter can be the lens adapter. Themethod can further include clamping an anterior adapter to the hand heldcomputer device having the camera, the anterior adapter including: avariable intensity light source, a clamp configured to engage with thehand held computer device, and a movable macro lens configured to movethe macro lens from a first position in coaxial alignment with anoptical axis of the camera to a second position outside of the opticalaxis of the camera, the macro lens configured to image an anteriorportion of the patient's eye. The method can further include adjustingthe variable intensity light source to provide a desired level of lightto the posterior portion of the patient's eye. The method can furtherinclude adjusting the variable intensity light source to provide adesired level of light to the anterior portion of the patient's eye. Themethod can further include moving the macro lens to be in coaxialalignment with the optical axis of the camera of the hand held computerdevice; moving the hand held computer device and anterior adapter tofocus on the anterior portion of the patient's eye; and taking an imageof the anterior portion of the patient's eye with the camera of the handheld computer device. The anterior adapter can further include a lightcollimating element and further include passing light from the variableintensity light source through the light collimating element to providecollimated light to the anterior portion or the posterior portion thepatient's eye. The method can further include providing a movablemodular optical light guide with the anterior adapter. The method canfurther include moving the modular optical light guide relative to theanterior adapter to a position in line with an optical light path of thevariable intensity light source. The method can further include passinglight from the variable-intensity light source through the optical lightguide. The modular optical light guide can further include a rhomboidprism with a first surface and a second surface and further includereflecting light from the variable intensity light source off of thefirst surface towards the second surface and reflecting light from thefirst surface off of the second surface to be substantially parallel tothe optical pathway of the hand held computer device camera. The modularoptical light guide can further include a rhomboid prism with a firstsurface and a second surface and further include reflecting light fromthe variable intensity light source off of the first surface towards thesecond surface and reflecting light from the first surface off of thesecond surface to substantially coincide with the optical pathway of thehand held computer device camera. The method can further include usingthe modular optical light guide for direct ophthalmoscopy with theanterior adapter to obtain a direct ophthalmoscopy image of thepatient's eye. The hand held computer device can be a smartphone,tablet, or other flatscreen computer device. The method can furtherinclude reversibly engaging the anterior adapter and the posterioradapter to form an interlocking connection between the anterior adapterand the posterior adapter.

BRIEF DESCRIPTION OF THE DRAWINGS

The novel features of the invention are set forth with particularity inthe claims that follow. A better understanding of the features andadvantages of the present invention will be obtained by reference to thefollowing detailed description that sets forth illustrative embodiments,in which the principles of the invention are utilized, and theaccompanying drawings of which:

FIG. 1 shows a modular adapter including a posterior adapter and ananterior adapter engaged with a smartphone in accordance with someembodiments.

FIG. 2 shows a side view of a modular adapter including a posterior anadapter and anterior adapter engaged with a smartphone in accordancewith some embodiments.

FIG. 3 shows a modular adapter including a posterior adapter and ananterior adapter engaged with a smartphone with the optical axis of thecamera in line with an optical axis of the adapter in accordance withsome embodiments.

FIG. 4 shows a modular adapter including a posterior adapter and ananterior adapter engaged with a smartphone with a macro lens rotatedaway from the optical axis of the smartphone camera in accordance withsome embodiments.

FIG. 5 shows a side view of a posterior adapter of a modular adapterengaged with a smartphone in accordance with some embodiments.

FIGS. 6-7 shows additional views of a posterior adapter of a modularadapter engaged with a smartphone in accordance with some embodiments.

FIGS. 8-10 show various views of an anterior adapter engaged with asmartphone in accordance with some embodiments.

FIG. 11 is a schematic illustration of a smartphone with a light sourceand a camera imaging an eye.

FIGS. 12-18 are schematic illustrations of various embodiments ofadapters that modify a light path of a light source.

FIG. 19A is a schematic illustration of an adapter modifying a lightpath of a light source in accordance with some embodiments.

FIG. 19B is a schematic illustration of an adapter modifying a lightpath of a light source in accordance with some embodiments.

FIG. 20 is a schematic illustration of an adapter modifying a light pathof a light source in combination with a modular adapter engaged with asmartphone in accordance with some embodiments.

DETAILED DESCRIPTION

Improved modular lens adapters systems are described herein. The modularlens adapter systems include a posterior adapter and an anterioradapter. The modular lens adapter systems can be used with a variety ofdifferent hand held computer devices having different dimensions anddifferent camera positions. The ability to quickly and easily engage theanterior adapter with hand held computer devices having differentdimensions and camera positions greatly increases the utility of thesystem.

The modular adapter systems described herein can be combined with aninexpensive hand held computer device to form a low-cost and mobileophthalmoscope that can be used to provide cost effective treatments toa variety of different patients. The present system allows, for example,the ability to treat patients in remote locations that do not haveaccess to high quality eye care clinics.

A modular lens adapter system or kit is provided for mobile anterior andposterior segment ophthalmoscopy. Equipped with various lens adaptermodules, respective lenses and a hand held computer device having acamera, a user is provided with tools for mobile ophthalmoscopy. Theuser can setup for various mobile ophthalmoscopy imaging applicationslike:

-   -   Posterior segment ophthalmoscopy using the ophthalmoscopy lens        adapter with the hand held computer device having a camera with        an internal variable intensity light source.    -   Posterior segment ophthalmoscopy using the ophthalmoscopy lens        adapter with the hand held computer device and an external        variable intensity light source.    -   Posterior segment ophthalmoscopy using the ophthalmoscopy lens        adapter with the hand held computer device using the variable        intensity light source of the anterior adapter with the macro        lens out of the optical path of the hand held computer device        and ophthalmoscopy lens.    -   Anterior segment ophthalmoscopy using the anterior adapter and a        macro lens with the hand held computer device optionally using        the variable intensity light source of the anterior adapter,        where the ophthalmoscopy lens adapter is detached from the hand        held computer device.    -   Anterior segment ophthalmoscopy using the anterior adapter with        macro lens with the hand held computer device and its internal        variable intensity light source, where the ophthalmoscopy lens        adapter is detached from the hand held computer device.

With the embodiments of the adapters described herein, eye carepractitioners can use their existing lenses to customize the modularlens adapter system in a cost-effective way, which allows for mobile andremote capture, viewing, and utilization of clinical images. The variousmodules are also adaptable to nearly any type of phone, tablet, or otherhand held computer device having a camera regardless of its dimensionsor presence of a protective case. The embodiments also address thereduced need for extra ophthalmic equipment, which is further importantin enabling a broad base of users.

The modular lens adapter system can be used with hand held computerdevices having different dimensions and camera locations. Examples ofhand held computer devices include: mobile imaging devices, phones,smartphones (e.g. iPhone), personal digital assistant (PDA), tabletcomputer devices (e.g. iPad, iPod, etc.), flatscreen computer device,high definition webcam (wired and wireless), as well as digital camerasand video cameras with wireless and/or Bluetooth connectivity, all withat least a camera option for making still images and/or video. Theexemplary embodiments are portrayed with an iPhone and different adaptermodules, although these embodiments can be quickly adjusted to othersmartphone brands and mobile devices of varying dimensions and cameralocations.

The modular adapter systems include an anterior adapter and a posterioradapter that can be used separately or together.

The anterior adapter can include a variable intensity light source, apower source for the variable intensity light source, a clamp configuredto removably engaged with the hand held computer device, and a movablemacro lens. The anterior adapter can be configured to removably engagewith the hand held computer device by engaging the clamp with the handheld computer device. The movable macro lens can move from a firstposition in coaxial alignment with an optical axis of the hand heldcomputer device camera to a second position outside of the optical axisof the camera. In one example the macro lens can be moved between thefirst position and the second position by rotating the macro lens and/ormacro lens holder about a macro lens hinge. A macro lens engagementsurface can be used to secure the macro lens holder and macro lens inthe first position. The macro lens can be used for imaging an anteriorportion of the patient's eye and moved out of the optical pathway of thecamera of the held computer device when using the posterior adapter toimage the patient's eye.

The macro lens may be a commercially available macro lens manufacturedspecifically for smartphones. The macro lens may have a focal lengthranging from about 1 cm to about 20 cm.

Preferably, the variable intensity light source is an LED light sourcewith an adjustable intensity that can be adjusted with, for example,dial control. The control element for the LED intensity may be a dial,but could also be, but not limited to, a knob, a sliding switch, ahaptic touch button, or a button.

The power source for the variable intensity light source can include aremovable battery source adapted to power the variable intensity lightsource. In some embodiments the variable intensity light sourcecomprises a light emitting diode (LED) or a plurality of LEDs.

The anterior adapter is designed to engage with a variety of differentsizes and thicknesses of hand held computer devices. The anterioradapter is configured to engage with the hand held computer deviceadapter at more than one position relative to the hand held computerdevice such that the anterior adapter can be lined up with the opticalaxis of the camera of the hand held computer device. This allows theanterior adapter to engage with more than one brand of hand heldcomputer device since different brands and models have differentdimensions and unique camera locations. For the anterior adapter theback area (e.g. contacting the smartphone) is adapted to the hand heldcomputer device.

In some embodiments the anterior adapter includes a clamp to secureitself relative to the hand held computer device. The clamp can includea spring to secure the clamp and anterior adapter relative to the handheld computer device. The clamp can include a first surface and a secondsurface with the first surface and second surface movable relative toeach other such that the first surface and second surface can apply acompressive force against the hand held computer device.

The anterior adapter can be used with the hand held computer device toobtain an image of an anterior portion of the patient's eye using themacro lens. Methods for imaging the anterior portion of the eye caninclude clamping the anterior adapter to a hand held computer devicehaving a camera, moving the macro lens to be in coaxial alignment withthe optical axis of the camera of the hand held computer device, movingthe hand held computer device and anterior adapter to focus on theanterior portion of the patient's eye, and receiving an image of theanterior portion of the patient's eye with the camera of the hand heldcomputer device.

The user can line up the optical axis of the camera with the opticalaxis of the anterior adapter prior to clamping the anterior adapter. Theclamp allows for quick and easy adjustment of the anterior adapterrelative to the smartphone to line the optical axis of the camera withthe optical axis of the anterior adapter and macro lens.

The variable intensity light source can be adjusted to provide thedesired level of light from the variable intensity light source to theanterior portion of the patient's eye. Many hand held computer deviceswith light sources do not offer easy control of the light source and/orprovide an easy way to provide lower levels of light suitable fordirecting at a patient's eye. The light sources on board the hand heldcomputer devices are often too bright to shine into the patient's eye.The variable intensity light sources described herein can be quickly andeasily adjusted to provide a low level of light that is sufficient toobtain an image of the eye while not being too bright to make thepatient uncomfortable.

The posterior adapter can include a mount, telescoping arm, and a lensmount. The mount can be configured to removably engage with the handheld computer device by contacting opposing sides of the hand heldcomputer device. The telescoping arm can have a first end and a secondend. The first end can be configured to removably engage with the mount.The second end can be configured to contact the lens mount. The lensmount can be configured to removably mount a posterior segmentophthalmoscopy lens configured for indirect ophthalmoscopy.

The telescoping arm allows for adjustment of the working distance(adjusting the focal point) between the hand held computer device and anophthalmoscopy lens mounted to ophthalmoscopy lens adapter via lensmount. In some embodiments the telescoping arm can position the lensmount from the mount in a range of 1 cm to 20 cm. Various othermechanisms could also work, such as folding or collapsing arm segmentswith joints and therefore the invention is not limited to telescopingsegments. The objective of the telescopic arms or even the folding orcollapsing arm segments is that the size can be minimized for easystorage. In one example with the same objective of minimizing space, thetelescoping arms could also be separated from each other.

The lens mount can be sized to accommodate an ophthalmoscopy lens in therange of 10D to 90D, such as a 14D, 20D, 22D, 28D, 30D, 40D, or 54D, 60,66, and 90D condensing lens for indirect ophthalmoscopy. The workingdistance between the lens mount and the hand held computer device can beabout 5.75″ in the case of an iPhone and a Volk Panretinal 2.2 lens, butwill vary depending on the combination of hand held computer devicecamera, ophthalmoscopy lens power, and the subject being examined. Forinstance, for certain combinations of patients and lenses, the workingdistance can be reduced approximately 2 inches, or lengthened toapproximately 10 inches. Ophthalmoscopy lenses can be easily mounted andremoved from the inner diameter of the lens mount. In a preferredembodiment, the inner diameter of lens mount has a slightly undersizedfit to allow gripping of the ophthalmoscopy lens for easy insertion andremoval. In another preferred embodiment, it would be desirable to makethe ring of lens mount more flexible to allow easy insertion and removalof the ophthalmoscopy lens. In other embodiments, a clamp mechanism canbe used to hold the lens. The clamp could utilize a ratchet typemechanism, a spring mechanism, an adjustable belt, a vice, an elasticband, or screws that can be adjusted to hold the lens in place. In oneexample, it could be desirable that the ophthalmoscopy lens adapter beminimized in size so that it can be stored in a pocket of a garment,e.g. a pocket of a doctor's coat.

In some embodiments the lens mount is configured to fold relative to thetelescoping arm. The lens mount can include an opening in an outerdiameter of the lens mount. The lens mount opening can be sized toaccommodate a shaft portion of the telescoping arm when the lens mountis in a folded position. In some embodiments the lens mount isconfigured to be folded to be parallel and flush with the telescopingarm.

The mount of the posterior adapter can accommodate hand held computerdevices with various dimensions. The mount of the posterior adapter candefine a dominant axis (e.g. y-axis in FIG. 1) with a length that can beadjusted to a plurality of different lengths. The mount can include afirst hand held computer device contact surface and a second hand heldcomputer device contact surface defining the dominant axis. In someembodiments the posterior adapter also includes a locking mechanismconfigured to hold the length of the dominant axis of the mount. Thelocking mechanism can also be configured to secure the telescoping armrelative to the mount. The telescoping arm can be moved along thedominant axis to the desired position and then locked into the desiredposition. In some embodiments the locking mechanism comprises a thumbscrew.

Methods of using the posterior adapter to image a posterior portion ofthe patient's eye are also provided. The methods can include securingthe mount of a posterior adapter to a hand held computer device,adjusting the telescoping arm along an axis of the mount to coaxiallyline up the lens mount with an optical axis of the camera of the handheld computer device, engaging a lens configured for indirectophthalmoscopy with the lens mount, moving the hand held computer deviceand the posterior adapter to focus on the posterior portion of thepatient's eye, adjusting a length of the telescoping arm to focus thecamera of the hand held computer device on an image of the posteriorportion of the patient's eye in the lens configured for indirectophthalmoscopy, and receiving an image of the posterior portion of thepatient's eye with the camera of the hand held computer device.

Securing the mount of the posterior adapter can include adjusting alength of the axis of the mount to accommodate a dimension of the handheld computer device. In one example securing the mount can includeengaging a first hand held computer device contact surface and a secondhand held computer device contact surface of the mount with the handheld computer device. The length of the axis of the mount can be lockedafter it has been sized to contact the hand held computer device tosecure the mount and posterior adapter to the hand held computer device.

The lock can further be used to secure the position of the telescopingarm along the dominant axis of the mount after lining up the opticalaxis of the lens mount with the optical axis the camera of the hand heldcomputer device. For example, by tightening the illustrated adjustabledial.

In some embodiments the modular lens adapter includes an open opticalpathway between the macro lens and the lens mount.

The modular lens adapter can include an optional patient face engagementsurface adjacent the lens mount.

The anterior and posterior adapters can be small and lightweight suchthat they can be placed in a pocket of the user.

In some embodiments the anterior adapter includes a light collimatingelement configured to be used with the variable intensity light source.The light collimating element can be movable from a position in anoptical light path of the variable intensity light source and a secondposition outside of the optical light path of the variable intensitylight source. In some embodiments the light collimating element isremovable from the anterior adapter. The light collimating element canbe used to modify a diffuse light, such as a diffuse light emitted bythe variable intensity light source in some embodiments, into acollimated light. Examples of light collimating elements include lensessuch as a spheroconvex lens or spherocylindrical lens, or masks ofvarious geometries including slit, rectangle, square, or circles ofvarying diameter such that the emitted light takes on the shape of thelens or mask (e.g. a slit-shaped, rectangular, or circular beam oflight). There may also be various filters such that the light emittedwith cobalt-blue or red-free, for instance.

In some embodiments the adapter can also include a modular optical lightguide. The modular optical light guide can be adapted to guide anoptical light path of the variable intensity light source to coincidewith an optical axis of the macro lens and hand held computer devicecamera. In some embodiments the modular optical light guide isconfigured for direct ophthalmoscopy with the anterior adapter. Themodular optical light guide can be used with the anterior adapter fordirect ophthalmoscopy to obtain a direct ophthalmoscopy image of thepatient's eye with the hand held computer device. For example, in someembodiments the modular optical light guide enables directophthalmoscopy of the retina and optic nerve. It also makes the lightmore coincident with the visual axis of the hand held computer device toenable improved image capture during indirect ophthalmoscopy with theposterior adapter.

In some embodiments the modular optical light guide includes a rhomboidprism. In one example, the rhomboid prism can include a first surfaceconfigured to reflect light from the variable intensity light sourcetowards the optical pathway of the hand held computer device camera anda second surface configured to reflect light from the first surface tobe substantially parallel to the optical pathway of the hand heldcomputer device camera. In one example, the rhomboid prism includes afirst surface configured to reflect light from the variable intensitylight source towards the optical pathway of the hand held computerdevice camera and a second surface configured to reflect light from thefirst surface to substantially coincide with the optical pathway of thehand held computer device camera. In some examples, the rhomboid prismhas reflective or partially reflective (and thus partially transparent)surfaces. In other examples, the light guide comprises hollow pathsconfigured with reflective and partially reflective surfaces to redirectlight along a desired pathway and ultimately to run coaxially with thevisual axis of the camera lens.

The modular optical light guide can be configured to be removable fromthe anterior adapter. In some embodiments the modular optical lightguide is configured to be movable relative to the variable intensitylight source. The modular optical light guide can be movable between aposition in line with the optical light path of the variable intensitylight source and a second position outside of the optical light path ofthe variable intensity light source. In some embodiments, this movementis facilitated by a hinge, a dial-mechanism (e.g. a carousel), or asliding mechanism, or a combination thereof. In some embodiments, thereare multiple modular optical light guides that provide light of variousproperties, shapes, and wavelengths. In some embodiments, the modularoptical light guide(s) are combined with masks or filters as describedabove.

In some embodiments the adapter includes a polarizing filter for one ofthe lenses and/or for the light source. Examples of polarizing filtersinclude a linear polarizing filter and a circularly polarizing filter.

FIG. 1 shows a modular adapter including a posterior adapter and ananterior adapter engaged with a smartphone in accordance with someembodiments. The posterior adapter 100 has a universal phone-mountingend 101 containing an adjustable dial 102 that locks the position of theshaft 103 in the x-y plane and the two brackets 104 and 105 also in thex-y plane so that the mount can grip devices of virtually any width. Onthe other end of the shaft is the lens mount 106 that is foldable sothat the mounted lens 122 shown in FIG. 4 can fold down onto the shaft.The lens mount 106 is movable in the z-axis direction to accommodatedifferent focal lengths of the lens being used and the refractive powerand axial length of the eye being examined. The adapter also has anoptional retractable face-rest element 107 that can be used to stabilizethe adapter on a patient's face, or alternatively on a user's hand orthumb during image acquisition. The lens mount 106 includes an interiorsurface 124 configured to removably receive and secure a lens 122 forindirect ophthalmoscopy.

The anterior adapter 108 is comprised of a clamp or clip 109, a lightsource 110, potentiometer 111 that controls the intensity of the lightsource 110, a light switch 112, a battery pack (internal to 113), andmovable macro lens (114). The movable macro lens 114 can rotate relativea macro lens hinge 126 between a first position (shown in FIG. 1) incoaxial alignment with an optical axis 120 of the hand held computerdevice camera to a second position outside of the optical axis of thecamera (shown in FIG. 4).

The anterior adapter includes a macro lens holder 129 configured to holdthe macro lens 114. The macro lens holder is engaged with the macro lenshinge 126 and can rotate about the macro lens hinge 126. The macro lensholder 129 is configured to engage with a macro lens engagement surface127 of the anterior adapter 108. The engagement surface 127 isconfigured to secure the macro lens 114 and macro lens holder 129 in thefirst position in coaxial alignment with the optical axis of the handheld computer device camera. The macro lens engagement surface 127 canprevent rotation of the macro lens 114, and macro lens holder 129 aboutthe macro lens hinge 126 to a position outside of the first position.Essentially, the macro lens engagement surface 127 can provide somefriction to keep the macro lens 114 in place while the macro lens 114 isbeing used. When the user is finished with the macro lens 114 then theycan push on the macro lens holder 129 to disengage the macro lens holder129 from the macro lens engagement surface 127 to rotate the macro lens114 and macro lens holder 129 about the macro lens hinge 126 to aposition outside of the first position. In some embodiments the macrolens engagement surface 127 includes a complementary shaped surface tothe macro lens holder 129. In some embodiments the macro lens engagementsurface 127 can include a friction surface, snap fit connection, otherlocking structures, and/or other complementary shapes that can be usedto secure the lens and hold it in the first position while the macrolens is in use.

The light source 110 can be positioned adjacent to the native cameralens 115 in order to provide near coaxial illumination with thevisual/optical axis of the camera lens. The high plus power lens andoptional light collimating element can converge the emitted light into acircular spot. The rhomboid prism and/or mirror system angles theemitted light so that it travels exactly co-axial with the visual axisof the camera lens. The polarizing filters screen out circularly,horizontally, or vertically polarized light to help reduce glare. Therhomboid prism and/or mirror system, by enabling co-axial light, in turnenables a direct ophthalmoscopic view of a patient's retina.

FIG. 2 shows a side view of a modular adapter including the posterioradapter 100 and anterior adapter 108 engaged with a smartphone 116. FIG.2 shows the anterior adapter 108 secured to the smartphone 116 withclamp 109.

FIG. 3 shows an optical axis 120 of the modular adapter in line with theoptical axis of the camera 115, macro lens 114, and lens mount 106. FIG.4 shows a modular adapter with a macro lens 114 rotated away from theoptical axis 120 of the camera. FIG. 4 shows the lens 122 and theoptical axis 120 of the camera substantially coincidental with theoptical axis of the lens 122 in the lens mount 106. FIG. 4 alsoillustrates an optional light-collimating element 121 adjacent to thelight source 110.

FIG. 5 shows a side view of a posterior adapter 100 engaged with asmartphone 100. The telescoping arm 103 includes a groove 130. Thegroove 130 allows the lens mount 106 to slide along the groove 130 sothat the user can position the lens 122 and lens mount 106 to focus theimage received by the camera 115 of the smartphone. The telescoping arm103 can also change to vary the length of the telescoping arm 103 alongthe Z-axis. The lens mount 106 can also fold relative to the groove 130to fold back along the telescoping arm 103 to make the device morecompact and allow for it to fit within the pocket of the physician oruser. For example the device can include a lens mount hinge between thetelescoping arm 103 and the lens mount 106 to facilitate folding of thelens mount 106 relative to the telescoping arm 103.

FIGS. 6-7 shows additional views of the posterior adapter 100 engagedwith the smartphone 116. The brackets 104 and 105 can move relative toeach other to increase or decrease the length of the brackets along theillustrated y-axis. This allows for the brackets 104, 105 to accommodatea hand held computer device having different widths. The bracket 104includes an opening 132. The bracket 105 includes an opening 134. Theopenings 132, 134 allow the telescoping arm 103 to move along the axisof the openings, such as the illustrated y-axis. The adjustable dial 102can be turned to secure the telescoping arm 103 relative to the brackets104, 105 and bracket openings 132, 134. For example, the adjustable dial102 can tighten a structure such that the dial engaged with and securesthe brackets 104, 105 relative to each other and both brackets 104, 105relative to the telescoping arm 103, thereby locking the posterioradapter 100 relative to the smartphone 116.

FIGS. 8-10 show various views of the anterior adapter 108 engaged withthe smartphone 116. The anterior adapter 108 can be held in positionrelative to the smartphone 116 with the clamp 109. The illustrated clamp109 includes a spring 136 that applies a compressive force with a firstsurface 138 of the clamp 109 and a second surface 140 of the clamp 109.The first surface 138 and second surface 140 of the clamp 109 secure theanterior adapter 108 relative to the smartphone 116. The clamp 109 canaccommodate devices having many different widths and dimensions. Theclamp 109 allows for the user to adjust the position of the anterioradapter 108 relative to the smartphone 116 and camera 115. The user canadjust the position of the anterior adapter 108 along the x-axis andy-axis to line up an optical axis of the camera 115 with the macro lens114 and the optical axis of the macro lens (e.g. optical axis 120 shownin FIG. 3).

In some embodiments the lens used on the lens mount, for example lensmount 106 depicted in the Figures, may be optionally secured in placeeither through an interlocking, tightening, or adhesive mechanism. Themount itself may be removable, for instance in the case of differentsized lens holders. The lens may be a conventional ophthalmoscopy lensmade from glass, or a plastic lens; the lens preferably has anantireflective coating and a scratch-resistance coating such as adiamond coating. The lens may or may not be disposable. In someembodiments, the anterior and posterior adapters are reversibly joinedor interlocked to create a stable, three-point fixation to the phone,and where the point of connection between the anterior and posterioradapters is modifiable.

In some embodiments an optional telescoping mechanism may be present onthe shaft 103 enabling different working distances, to accommodate eyeswith different axial lengths ranging from newborns with small eyes tolong adult eyes, as well as different refractive errors ranging fromhyperopic to myopic.

Examples of optional structures that can be used with the anterioradapter include an optional high plus power lens placed in front of thelight source, and an optional rhomboid prism, optical light guide,mirrors, and polarizing filters that can be mounted over the lightsource and in front of the camera lens.

In some embodiments the LED may be emitted as a diffuse light, acollimated (spot) light, a slit, a square, or a rectangle. It may bewhite, blue, or red-free in color.

In some embodiments an enclosure may be present to connect the cameralens and LED to the lens within a cylindrical housing that istelescopable and/or retractable in order to position the lens atdifferent working distances from the phone. In this setup, the shaft 103may be optional, i.e. the enclosure serves as the holder for the distallens. Additional lenses may be positioned between the distal lens andthe camera to create a Galilean or Astronomical telescope system withdifferent mounts of optical magnification.

FIG. 11 is a schematic illustration of a smartphone 116 with a lightsource 117 and a camera 115 imaging an eye 195 without the use of amodular adapter. The camera 115 has an optical path 205 directed at theeye 195. FIGS. 12-18 are schematic illustrations of various embodimentsof adapters used with the smartphone 116 that modify a light path of alight source.

FIGS. 12-20 illustrate embodiments of optical light guides. The opticallight guides can be used to direct the light from a light source on thehand held computer device and/or the anterior adapter (e.g. variableintensity light source) to be in line with the optical axis of a cameraon the hand held computer device. The use of the optical light guide canallow for the imaging of the retina and optic nerve via directophthalmoscopy. For example, the light guide can shape the light path tofacilitate providing light from the variable intensity light source tothe optic nerve and retina along the axis of the camera of the hand heldcomputer device. The camera of the hand held imaging device can thenobtain a direct image of the retina and optic nerve that are illuminatedby the light directed through the optical light guide. A red-freefiltered illumination may be used in this case.

FIG. 12 illustrates an embodiment of an optical light guide 200including a rhomboid prism 202 used with an anterior adapter 108 and asmartphone 116. The rhomboid prism 202 includes a first surface 204 anda second surface 206 for directing light emitted from the light source110 of the anterior adapter 108 along an optical path 208. As shown inFIG. 12, the first surface 204 directs light emitted from the lightsource 110 along optical path 208 towards the second surface 206. Thesecond surface 206 reflects the light reflected off of the first surface204 along the optical path 208 towards the eye 195. The optical path 208through the optical light guide 200 lines the optical path 208 exitingthe optical light guide to be substantially parallel to the optical path205 of the camera 115. In some embodiments the optical light guide 200can line up the optical path 208 to substantially coincide with theoptical path 205 of the camera 115. The optical light guide 200 can beused directly with the smartphone 116 and light source 117 or can bepart of the anterior adapter 108 to direct the light emitted from thelight source 110.

FIG. 13 illustrates an embodiment of an optical light guide 220 usedwith an anterior adapter 108 and a smartphone 116. The optical lightguide 220 includes a polarizer Y 222, first mirror surface 224,polarizer X 228, and a second beamsplitter surface 226 for directinglight emitted from the light source 110 of the anterior adapter 108along an optical path 230. As shown in FIG. 13, the first mirror surface224 directs light emitted from the light source 110 along optical path230 towards the second beamsplitter surface 226. The second beamsplittersurface 226 reflects the light reflected off of the first mirror surface224 along the optical path 230 towards the eye 195. The optical path 230through the optical light guide 220 lines the optical path 230 exitingthe optical light guide 220 to substantially coincide with the opticalpath 205 of the camera 115. The optical light guide 220 also passes thelight from the light source 110 through the polarizer Y 222. The opticallight guide 220 also adds a polarizer 228 to the optical path 205 of thecamera 115. The optical light guide 220 can be used directly with thesmartphone 116 and light source 117 or can be part of the anterioradapter 108 to direct light emitted from the light source 110.

FIG. 14 illustrates an embodiment of an optical light guide 240 usedwith an anterior adapter 108 and a smartphone 116. The optical lightguide 240 includes a first mirror surface 242 and a second beamsplittersurface 244 for directing light emitted from the light source 110 of theanterior adapter 108 along an optical path 246. As shown in FIG. 14, thefirst mirror surface 242 directs light emitted from the light source 110along optical path 246 towards the second beamsplitter surface 244. Thesecond beamsplitter surface 244 reflects the light reflected off of thefirst mirror surface 242 along the optical path 246 towards the eye 195.The optical path 246 through the optical light guide 240 lines theoptical path 246 exiting the optical light guide 240 to substantiallycoincide with the optical path 205 of the camera 115. The optical lightguide 240 can be used directly with the smartphone 116 and light source117 or can be part of the anterior adapter 108 to direct light emittedfrom the light source 110.

FIG. 15 illustrates an embodiment of an optical light guide 260 with asolid prism 262 used with an anterior adapter 108 and a smartphone 116.The solid prism 262 includes a first mirror surface 264 and a secondsurface with a beamsplitter coating 266 for directing light emitted fromthe light source 110 of the anterior adapter 108 along an optical path268. As shown in FIG. 15, the first mirror surface 264 of the prism 262directs light emitted from the light source 110 along optical path 268towards the second surface with the beamsplitter coating 266. The secondsurface with the beamsplitter surface 266 reflects the light reflectedoff of the first mirror surface 264 along the optical path 268 towardsthe eye 195. The optical path 268 through the optical light guide 260lines the optical path 268 exiting the optical light guide 260 tosubstantially coincide with the optical path 205 of the camera 115. Theoptical light guide 260 can be used directly with the smartphone 116 andlight source 117 or can be part of the anterior adapter 108 to directlight emitted from the light source 110.

FIG. 16 illustrates an embodiment of an optical light guide 280 usedwith an anterior adapter 108 and a smartphone 116. The optical lightguide 280 includes a first mirror surface 282 and a second mirrorsurface 284 for directing light emitted from the light source 110 of theanterior adapter 108 along an optical path 286. As shown in FIG. 16, thefirst mirror surface 282 directs light emitted from the light source 110along optical path 286 towards the second mirror surface 284. The secondmirror surface 284 reflects the light reflected off of the first mirrorsurface 282 along the optical path 286 towards the eye 195. The opticalpath 286 through the optical light guide 280 lines the optical path 286exiting the optical light guide 280 to be offset from but substantiallyparallel with the optical path 205 of the camera 115. The optical lightguide 280 can be used directly with the smartphone 116 and light source117 or can be part of the anterior adapter 108 to direct light emittedfrom the light source 110.

FIG. 17 illustrates an embodiment of an optical light guide 300 with aprism 302 used with an anterior adapter 108 and a smartphone 116. Theprism 302 includes a first surface 304 and a second surface 306 fordirecting light emitted from the light source 110 of the anterioradapter 108 along an optical path 308. As shown in FIG. 17, the firstsurface 302 directs light emitted from the light source 110 alongoptical path 308 towards the second surface 306. The second surface 306reflects the light reflected off of the first surface 304 along theoptical path 308 towards the eye 195. The optical path 308 through theoptical light guide 300 lines the optical path 308 exiting the opticallight guide 300 to be offset from but substantially parallel with theoptical path 205 of the camera 115. The optical path 205 of the camera115 passes through the optical light guide 300 and prism 302 in FIG. 17.The optical light guide 308 can be used directly with the smartphone 116and light source 117 or can be part of the anterior adapter 108 todirect light emitted from the light source 110.

FIG. 18 illustrates an embodiment of an optical light guide 320 usedwith an anterior adapter 108 and a smartphone 116. The optical lightguide 320 includes a first mirror surface 322 and a second mirrorsurface 324 for directing light emitted from the light source 110 of theanterior adapter 108 along an optical path 326. As shown in FIG. 18, thefirst mirror surface 322 directs light emitted from the light source 110along optical path 326 towards the second mirror surface 324. The secondmirror surface 324 reflects the light reflected off of the first mirrorsurface 322 along the optical path 326 towards the eye 195. The opticalpath 326 through the optical light guide 320 lines the optical path 326exiting the optical light guide 320 to be offset from but substantiallyparallel with the optical path 205 of the camera 115. The optical lightguide 320 can be used directly with the smartphone 116 and light source117 or can be part of the anterior adapter 108 to direct light emittedfrom the light source 110.

FIGS. 19A-19B are schematic illustrations of a cross sectional view ofan optical light guide 400 with an anterior adapter 108 and smartphone116. FIG. 20 shows an isometric view of the optical light guide 400 withthe anterior adapter 108 and smartphone 116. The illustrated opticallight guide 400 includes a rhomboid prism 402. In other embodiments anyof the mirror systems shown in the previous figures and described hereincan be used. The rhomboid prism 402 includes a first surface 404 and asecond surface 406 for directing light emitted from the light source 117along an optical path 408. The first surface 404 directs light emittedfrom the light source 110 of the anterior adapter 108 along optical path408 towards the second surface 406. The second surface 406 reflects thelight reflected off of the first surface 404 along the optical path 408towards the eye 195. The optical path 408 through the optical lightguide 400 lines the optical path 408 exiting the optical light guide 400to substantially coincide with the optical path 205 of the camera 115.In some embodiments the optical light guide 200 can line up the opticalpath 208 to substantially parallel but offset from the optical path 205of the camera 115. The optical light guide 400 can move relative to theanterior adapter and optical axis 205 of the camera 115. For example theoptical light guide 400 can move from a first position (shown in FIGS.19A, 19B, and 20) with the optical path 408 in line with the opticalpath 205 of the camera 115 to a second position where the optical lightguide 400 does not affect or overlap with the light source 110 oroptical path 205 of the camera 115.

In some embodiments the adapter described herein can use the lightsource from the hand held computer device. For example, the anterioradapter can allow light from the hand held computer device to passthrough the anterior adapter and travel along the path of the opticallight guide. FIG. 19B illustrates an embodiment of the anterior adapter108 that includes a light pass through or window 150. The pass through150 allows the light source 117 from the smartphone 116 to pass througha portion of the anterior adapter 108 and go through the optical lightguide 400 as shown in FIG. 19B. The illustrated optical light guide 400includes a rhomboid prism 402. The rhomboid prism 402 includes a firstsurface 404 and a second surface 406 for directing light emitted fromthe light source 117 along an optical path 408. After the light passesthrough the window 150, the first surface 404 directs the light emittedfrom the light source 117 of the smartphone 116 along optical path 408towards the second surface 406. The second surface 406 reflects thelight reflected off of the first surface 404 along the optical path 408towards the eye 195. The optical path 408 through the optical lightguide 400 lines the optical path 408 exiting the optical light guide 400to substantially coincide with the optical path 205 of the camera 115.In some embodiments the optical light guide 200 can line up the opticalpath 208 to substantially parallel but offset from the optical path 205of the camera 115. The optical light guide 400 can move relative to theanterior adapter and optical axis 205 of the camera 115. For example theoptical light guide 400 can move from a first position (shown in FIGS.19A, 19B, and 20) with the optical path 408 in line with the opticalpath 205 of the camera 115 to a second position where the optical lightguide 400 does not affect or overlap with the light source 117 oroptical path 205 of the camera 115.

In some embodiments the telescoping arm can be permanently or reversiblymounted to the posterior mount or a case for the hand held device. Ineither case, the telescoping arm may be foldable such that the arm andlens mount distal to it are moved aside to allow the user to hold themobile device closer to the patient's eye when using, for example, theanterior adapter. The telescoping arm may be attached to the case of thephone either through a two-point fixation undersized gripping mechanismas shown in the drawings, or through other mechanisms such as adepression within the case that fits the telescoping arm (female-maleconnectivity), a reversible locking fit wherein a button is pressed torelease the arm from the case, a magnetic attachment mechanism, or asuction attachment mechanism.

In some embodiments the aperture of the LED light source could beadjustable to create varying diameters for the collimated beam. In someembodiments a collimating light element can be used in combination withthe light source. Blue, red-free, and other types of lighting may beused, and infrared lighting may also be used. In addition, variousfilters could be used for the light source, for instance, to physicallyreduce the intensity of the light. This method could be used in place ofthe variable intensity light source, to provide one or more barrier-typefilters for the light. Examples of such filters are neutral densityfilters and polarizing filters.

In some embodiments certain elements may be positioned in front of thecamera lens to enhance image quality. Such elements include, forexample, additional lenses that will serve to increase the magnificationof the virtual image created by the ophthalmoscopy lens seen on the handheld computer device screen (e.g. to enable to occupy a greaterpercentage of the screen area) as well as filtering elements such aspolarizing filters, neutral density filters, and pinhole filters thatcan reduce glare and light scatter.

In some embodiments the macro lens could include a rotating or slidinglens or filter set where the user can select from macro, blue filter,high magnification, and wide angle lenses by rotation the lens set infront of the lens of the hand held computer device.

In some embodiments the anterior adapter could further include an eyerest, e.g. a circular protrusion around the macro lens which could beplace around the eye, to assist in positioning and stabilizing theanterior adapter and hand held computer device system and its variousmodular forms in front of the eye when using the anterior adapter toobtain an image of the eye.

In some embodiments the variable intensity external light source couldbe used with or without a mirror system or fiber optic element to guidethe light.

In some embodiments an external fixation target could be added for theopposite eye that can be a blinking light or other form of adjustablefixation target. A moveable extension with a blinking light tip could beplugged into a phone audio jack or directly to the adapter itself (suchas to the telescoping shaft or another part of either the anterior orposterior adapter) to direct a patient's gaze toward the light.

In some embodiments the LED light could be focused into an adjustableslit beam that can be directed through the cornea at an angle, mimickingthe action of a traditional slit lamp. The LED light may also be set toa fixed intensity (without a variable intensity function).

In some embodiments the system could be enhanced to have a dedicatedsoftware application running on the hand held computer device to assistin image capture, light control, image analysis, image enhancement, datastorage and data sharing as are common features of applications runningon, for example, smartphones.

When a feature or element is herein referred to as being “on” anotherfeature or element, it can be directly on the other feature or elementor intervening features and/or elements may also be present. Incontrast, when a feature or element is referred to as being “directlyon” another feature or element, there are no intervening features orelements present. It will also be understood that, when a feature orelement is referred to as being “connected”, “attached” or “coupled” toanother feature or element, it can be directly connected, attached orcoupled to the other feature or element or intervening features orelements may be present. In contrast, when a feature or element isreferred to as being “directly connected”, “directly attached” or“directly coupled” to another feature or element, there are nointervening features or elements present. Although described or shownwith respect to one embodiment, the features and elements so describedor shown can apply to other embodiments. It will also be appreciated bythose of skill in the art that references to a structure or feature thatis disposed “adjacent” another feature may have portions that overlap orunderlie the adjacent feature.

Terminology used herein is for the purpose of describing particularembodiments only and is not intended to be limiting of the invention.For example, as used herein, the singular forms “a”, “an” and “the” areintended to include the plural forms as well, unless the context clearlyindicates otherwise. It will be further understood that the terms“comprises” and/or “comprising,” when used in this specification,specify the presence of stated features, steps, operations, elements,and/or components, but do not preclude the presence or addition of oneor more other features, steps, operations, elements, components, and/orgroups thereof. As used herein, the term “and/or” includes any and allcombinations of one or more of the associated listed items and may beabbreviated as “/”.

Spatially relative terms, such as “under”, “below”, “lower”, “over”,“upper” and the like, may be used herein for ease of description todescribe one element or feature's relationship to another element(s) orfeature(s) as illustrated in the figures. It will be understood that thespatially relative terms are intended to encompass differentorientations of the device in use or operation in addition to theorientation depicted in the figures. For example, if a device in thefigures is inverted, elements described as “under” or “beneath” otherelements or features would then be oriented “over” the other elements orfeatures. Thus, the exemplary term “under” can encompass both anorientation of over and under. The device may be otherwise oriented(rotated 90 degrees or at other orientations) and the spatially relativedescriptors used herein interpreted accordingly. Similarly, the terms“upwardly”, “downwardly”, “vertical”, “horizontal” and the like are usedherein for the purpose of explanation only unless specifically indicatedotherwise.

Although the terms “first” and “second” may be used herein to describevarious features/elements (including steps), these features/elementsshould not be limited by these terms, unless the context indicatesotherwise. These terms may be used to distinguish one feature/elementfrom another feature/element. Thus, a first feature/element discussedbelow could be termed a second feature/element, and similarly, a secondfeature/element discussed below could be termed a first feature/elementwithout departing from the teachings of the present invention.

Throughout this specification and the claims which follow, unless thecontext requires otherwise, the word “comprise”, and variations such as“comprises” and “comprising” means various components can be co jointlyemployed in the methods and articles (e.g., compositions and apparatusesincluding device and methods). For example, the term “comprising” willbe understood to imply the inclusion of any stated elements or steps butnot the exclusion of any other elements or steps.

As used herein in the specification and claims, including as used in theexamples and unless otherwise expressly specified, all numbers may beread as if prefaced by the word “about” or “approximately,” even if theterm does not expressly appear. The phrase “about” or “approximately”may be used when describing magnitude and/or position to indicate thatthe value and/or position described is within a reasonable expectedrange of values and/or positions. For example, a numeric value may havea value that is +/−0.1% of the stated value (or range of values), +/−1%of the stated value (or range of values), +/−2% of the stated value (orrange of values), +/−5% of the stated value (or range of values), +/−10%of the stated value (or range of values), etc. Any numerical valuesgiven herein should also be understood to include about or approximatelythat value, unless the context indicates otherwise. For example, if thevalue “10” is disclosed, then “about 10” is also disclosed. Anynumerical range recited herein is intended to include all sub-rangessubsumed therein. It is also understood that when a value is disclosedthat “less than or equal to” the value, “greater than or equal to thevalue” and possible ranges between values are also disclosed, asappropriately understood by the skilled artisan. For example, if thevalue “X” is disclosed the “less than or equal to X” as well as “greaterthan or equal to X” (e.g., where X is a numerical value) is alsodisclosed. It is also understood that the throughout the application,data is provided in a number of different formats, and that this data,represents endpoints and starting points, and ranges for any combinationof the data points. For example, if a particular data point “10” and aparticular data point “15” are disclosed, it is understood that greaterthan, greater than or equal to, less than, less than or equal to, andequal to 10 and 15 are considered disclosed as well as between 10 and15. It is also understood that each unit between two particular unitsare also disclosed. For example, if 10 and 15 are disclosed, then 11,12, 13, and 14 are also disclosed.

Although various illustrative embodiments are described above, any of anumber of changes may be made to various embodiments without departingfrom the scope of the invention as described by the claims. For example,the order in which various described method steps are performed mayoften be changed in alternative embodiments, and in other alternativeembodiments one or more method steps may be skipped altogether. Optionalfeatures of various device and system embodiments may be included insome embodiments and not in others. Therefore, the foregoing descriptionis provided primarily for exemplary purposes and should not beinterpreted to limit the scope of the invention as it is set forth inthe claims.

The examples and illustrations included herein show, by way ofillustration and not of limitation, specific embodiments in which thesubject matter may be practiced. As mentioned, other embodiments may beutilized and derived there from, such that structural and logicalsubstitutions and changes may be made without departing from the scopeof this disclosure. Such embodiments of the inventive subject matter maybe referred to herein individually or collectively by the term“invention” merely for convenience and without intending to voluntarilylimit the scope of this application to any single invention or inventiveconcept, if more than one is, in fact, disclosed. Thus, althoughspecific embodiments have been illustrated and described herein, anyarrangement calculated to achieve the same purpose may be substitutedfor the specific embodiments shown. This disclosure is intended to coverany and all adaptations or variations of various embodiments.Combinations of the above embodiments, and other embodiments notspecifically described herein, will be apparent to those of skill in theart upon reviewing the above description.

What is claimed is:
 1. A method of imaging an anterior portion of apatient's eye, the method comprising: clamping an anterior adapter to ahand held computer device having a camera, the anterior adaptercomprising: a variable intensity light source, a clamp configured toengage with the hand held computer device, and a movable macro lensconfigured to move the macro lens from a first position in coaxialalignment with an optical axis of the camera to a second positionoutside of the optical axis of the camera, the macro lens configured toimage an anterior portion of the patient's eye; moving the macro lens tobe in coaxial alignment with the optical axis of the camera of the handheld computer device; securing the macro lens in the first position byrotating the macro lens about a macro lens hinge of the anterior adapterand engaging the macro lens with a macro lens engagement surface of theanterior adapter, the macro lens engagement surface configured to securethe macro lens in the first position in coaxial alignment with theoptical axis of the hand held computer device camera and preventrotation of the macro lens about the macro lens hinge to a positionoutside of the first position; moving the hand held computer device andanterior adapter to focus on the anterior portion of the patient's eye;and receiving an image of the anterior portion of the patient's eye withthe camera of the hand held computer device.
 2. The method of claim 1,further comprising: adjusting the variable intensity light source toprovide a desired level of light from the variable intensity lightsource to the anterior portion of the patient's eye.
 3. The method ofclaim 1, further comprising: lining up the optical axis of the camerawith an optical axis of the anterior adapter prior to clamping theanterior adapter.
 4. The method of claim 1, wherein the hand heldcomputer device is a smartphone, tablet, or other flatscreen computerdevice.
 5. The method of claim 1, further comprising reversibly engagingthe anterior adapter and the posterior adapter to form an interlockingconnection between the anterior adapter and the posterior adapter. 6.The method of claim 1 further comprising: a light collimating elementconfigured for use with the variable intensity light source wherein thelight collimating element is moveable into a first position in anoptical path of the variable intensity light source and a secondposition outside of the optical path of the variable intensity lightsource.
 7. The method of claim 6 further comprising: positioning a lensor a mask in the optical path of the variable intensity light sourcewhen the collimating light source is moved into the first position. 8.The method of claim 1 further comprising filtering the light emitted bythe variable intensity light source.
 9. The method of claim 8 whereinafter the filtering step the light is blue.
 10. A method of imaging aposterior portion of a patient's eye, the method comprising: clamping ananterior adapter to the hand held computer device having the camera, theanterior adapter comprising: a variable intensity light source, a clampconfigured to engage with the hand held computer device, and a movablemacro lens configured to move the macro lens from a first position incoaxial alignment with an optical axis of the camera to a secondposition outside of the optical axis of the camera, the macro lensconfigured to image an anterior portion of the patient's eye; movingsaid macro lens to the second position outside the optical axis of thecamera; securing a mount of a posterior adapter to a hand held computerdevice comprising a camera, the posterior adapter comprising atelescoping arm with a first end and a second end, the first endconfigured to removably engage with the mount and the second endconfigured to contact a lens mount configured to removably mount aposterior segment ophthalmoscopy lens configured for indirectophthalmoscopy; adjusting the telescoping arm along an axis of the mountto coaxially line up the lens mount with an optical axis of the cameraof the hand held computer device; engaging a lens configured forindirect ophthalmoscopy with the lens mount; moving a modular opticallight guide relative to the anterior adapter to a position in line withan optical light path of the variable intensity light source; passinglight from the variable-intensity light source through the modularoptical light guide; moving the hand held computer device and theposterior adapter to focus on the posterior portion of the patient'seye; adjusting a length of the telescoping arm to focus the camera ofthe hand held computer device on an image of the posterior portion ofthe patient's eye in the lens configured for indirect ophthalmoscopy;and receiving an image of the posterior portion of the patient's eyewith the camera of the hand held computer device, wherein, the modularoptical light guide further comprising a rhomboid prism with a firstsurface and a second surface and further comprising reflecting lightfrom the variable intensity light source off of the first surfacetowards the second surface and reflecting light from the first surfaceoff of the second surface to be substantially parallel to the opticalpathway of the hand held computer device camera or to substantiallycoincide with the optical pathway of the hand held computer devicecamera.
 11. The method of claim 10, further comprising securing themount of the posterior adapter by adjusting a length of the axis of themount to accommodate a dimension of the hand held computer device. 12.The method of claim 11, further comprising engaging a first hand heldcomputer device contact surface and a second hand held computer devicecontact surface of the mount with the hand held computer device.
 13. Themethod of claim 11, further comprising: locking a length of the axis ofthe mount to secure the mount relative to the hand held computer device.14. The method of claim 13, further comprising locking a position of thetelescoping arm along the axis of the mount after adjusting thetelescoping arm along the axis of the mount to coaxially line up thelens mount with the optical axis of the camera of the hand held computerdevice.
 15. The method of claim 10, further comprising: adjusting thevariable intensity light source to provide a desired level of light tothe posterior portion of the patient's eye.
 16. The method of claim 10,further comprising adjusting the variable intensity light source toprovide a desired level of light to the anterior portion of thepatient's eye.
 17. The method of claim 16, further comprising: movingthe macro lens to be in coaxial alignment with the optical axis of thecamera of the hand held computer device; moving the hand held computerdevice and anterior adapter to focus on the anterior portion of thepatient's eye; and taking an image of the anterior portion of thepatient's eye with the camera of the hand held computer device.
 18. Themethod of claim 10, further comprising passing light from the variableintensity light source through a light collimating element to providecollimated light to the anterior portion or the posterior portion thepatient's eye.
 19. The method of claim 10, further comprising obtaininga direct ophthalmoscopy image of the patient's eye using the modularoptical light guide for direct ophthalmoscopy with the anterior adapter.20. The method of any of claim 10, wherein the hand held computer deviceis a smartphone, tablet, or other flatscreen computer device.
 21. Themethod of any of claim 10, further comprising reversibly engaging theanterior adapter and the posterior adapter to form an interlockingconnection between the anterior adapter and the posterior adapter. 22.The method of claim 10, further comprising: powering the variableintensity light source using a removeable battery source.
 23. The methodof claim 10 further comprising: engaging a patient engagement surfaceadjacent the lens mount to a portion of a face of the patient.